Heat capacity Guide, Meaning , Facts, Information and Description
Heat capacity (abbreviated Cth or just C, also called thermal capacity) is the ability of matter to store heat. The heat capacity of a certain amount of matter is the quantity of heat (measured in Joules) required to raise its temperature by one kelvin. The SI unit for heat capacity is J/K (joule per kelvin).
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2 Thermal capacitance 3 Gas Phase Heat Capacities 4 See also |
The Specific heat capacity of a substance (abbreviated cp or s) is the heat required to raise the temperature of one kilogram of the substance by one kelvin. The SI unit for Specific heat capacity is joule per kilogram-kelvin (J/kgK). Hence the heat capacity is the specific heat capacity multiplied by the mass.
C is the heat capacity (measured in J/K)
m is mass (measured in kilograms)
s is specific heat capacity (measured in J/kgK)
Heat capacity is related to thermal capacitance by the formula
Cth is the thermal capacitance
V is the volume (measured in m3)
ρ is the density (measured in kg/m3)
cp is the specific heat capacity (measured in J/kgK at constant pressure)
m is the mass (measured in kg)
The product ρ · cp is known as volumetric heat capacity, thermal capacitance or (confusingly) thermal capacity, and has units of J/m3·K. Dulong and Petit predicted in 1818 that ρcp would be constant for all solids (the Dulong-Petit law). In fact, the quantity varies from about 1.2 to 4.5 J/m3K. For fluids it is in the range 1.3 to 1.9, and for ideal monatomic gases it is a constant 0.001 J/m3K.
E is the input energy (measured in Joules)
T is the temperature (measured in Kelvins)
R is the ideal gas constant, (8.314570[70] J K-1mol-1)
In the case of a monatomic gas such as helium under constant volume, if it assumed that no electronic or nuclear quantum excitations occur, each molecule has only 3 degrees of translational freedom. This is because there is one for each of the vector components of momentum in the x, y, and z directions. This leads to the equation
n is the number of moles of molecules present in the container
The following table shows experimental molar constant volume heat capacity measurements taken for each noble monatomic gas (at 1 atm and 25°C):
Specific heat capacity
Main article: Specific heat capacity.
whereThermal capacitance
or, more simply,
where Gas Phase Heat Capacities
According to the Equipartition Theorem from classical statistical mechanics, any input of energy into a closed system composed of N molecules is evenly divided among the degrees of freedom available to each molecule. It can be shown, for each degree of freedom, that
where
where
| Monatomic Gas | Cv,m | Cv,m |
| He | 12.5 | 1.50 |
| Ne | 12.5 | 1.50 |
| Ar | 12.5 | 1.50 |
| Kr | 12.5 | 1.50 |
| Xe | 12.5 | 1.50 |
It is apparent from the table that the experimental heat capacities of the monatomic noble gases agrees with this simple application of statistical mechanics to a very high degree. In the somewhat more complex case of an ideal gas of diatomic molecules, the presence of internal degrees of freedom are apparent. In addition to the three translational degrees of freedom, there are rotational and vibrational degrees of freedom. In general, there are three degrees of freedom f per atom in the molecule na
| Diatomic Gas | Cv,m | Cv,m |
| H2 | 20.18 | 2.427 |
| CO | 20.2 | 2.43 |
| N2 | 19.9 | 2.39 |
| Cl2 | 24.1 | 2.90 |
| Br2 | 32.0 | 3.84 |
From the above table, clearly there is a problem with the above theory. All of the diatomics examined have heat capacities that are lower than those predicted by the Equipartition theorem, except . However, as the atoms composing the molecules become heavier, the heat capacities move closer to their expected values. One of the reasons for this phenomenon is the quantization of vibrational, and to a lesser extent, rotational states. In fact, if it is assumed that the molecules remain in their lowest energy vibrational state because the interlevel energy spacings are large, the predicted constant volume heat capacity for a diatomic molecule becomes